TY - GEN
T1 - GPS Measurements anomaly and continuous GPS carrier-phase time transfer
AU - Yao, Jian
AU - Levine, Judah
PY - 2014
Y1 - 2014
N2 - The wide application of GPS carrier-phase (CP) time transfer is limited by the problem of boundary discontinu-ity (BD). The discontinuity has two categories. One is "day boundary discontinuity," which has been studied extensively and can be solved by a few methods [1-5]. The other category of discontinuity, called "anomaly boundary discontinuity (anomaly-BD)," comes from a GPS-measurements data anomaly. This paper focuses on the second category of discontinuity (i.e., anomaly-BD). We first demonstrate that a few minutes of GPS-measurements data anomaly are enough to lead to a dis-continuity of more than 200 picoseconds in the GPS CP time transfer. To eliminate the anomaly-BD, we propose a simple, but powerful strategy, i.e., polynomial curve-fitting for the anomaly. The fitted phase measurement is typically less than 3 cm from the original phase measure-ment, in terms of the root mean square (RMS). And the fitted code measurement is typically less than 80 cm from the original code measurement. If we replace the anomaly with the fitted data, we can avoid the re-estimation of the phase ambiguities after the anomaly. Thus, the anomaly-BD at the anomaly should disappear. Tests show that the curve-fitting strategy works very well for up to 20 min of GPS-measurements data anomaly.
AB - The wide application of GPS carrier-phase (CP) time transfer is limited by the problem of boundary discontinu-ity (BD). The discontinuity has two categories. One is "day boundary discontinuity," which has been studied extensively and can be solved by a few methods [1-5]. The other category of discontinuity, called "anomaly boundary discontinuity (anomaly-BD)," comes from a GPS-measurements data anomaly. This paper focuses on the second category of discontinuity (i.e., anomaly-BD). We first demonstrate that a few minutes of GPS-measurements data anomaly are enough to lead to a dis-continuity of more than 200 picoseconds in the GPS CP time transfer. To eliminate the anomaly-BD, we propose a simple, but powerful strategy, i.e., polynomial curve-fitting for the anomaly. The fitted phase measurement is typically less than 3 cm from the original phase measure-ment, in terms of the root mean square (RMS). And the fitted code measurement is typically less than 80 cm from the original code measurement. If we replace the anomaly with the fitted data, we can avoid the re-estimation of the phase ambiguities after the anomaly. Thus, the anomaly-BD at the anomaly should disappear. Tests show that the curve-fitting strategy works very well for up to 20 min of GPS-measurements data anomaly.
KW - Anomaly boundary discontinuity (anomaly-BD)
KW - Boundary discontinuity
KW - Carrier phase
KW - Curve fitting
KW - GPS
KW - Precise point position-ing (PPP)
KW - Time transfer
UR - https://www.scopus.com/pages/publications/84943241315
M3 - Conference contribution
AN - SCOPUS:84943241315
T3 - Proceedings of the Annual Precise Time and Time Interval Systems and Applications Meeting, PTTI
SP - 164
EP - 169
BT - 46th Annual Precise Time and Time Interval Systems and Applications Meeting, PTTI 2014
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 46th Annual Precise Time and Time Interval Systems and Applications Meeting, PTTI 2014
Y2 - 1 December 2014 through 4 December 2014
ER -